Rat Jugular Vein and Carotid Artery Catheterization for Acute Survival Studies
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Rat Jugular Vein and Carotid Artery Catheterization for Acute Survival Studies
Rat Jugular Vein and Carotid Artery Catheterization for Acute Survival Studies A Practical Guide Angela Heiser Foreword by John H.K. Liu
Angela Heiser West Roxbury, MA 02132 USA
Library of Congress Control Number: 2006936342 ISBN-10: 0-387-49414-6 e-ISBN-10: 0-387-49416-2 ISBN-13: 978-0-387-49414-2 e-ISBN-13: 978-0-387-49416-6 Printed on acid-free paper. 2007 Springer Science+Business Media, LLC All rights reserved. This work may not be translated or copied in whole or in part without the written permission of the publisher (Springer Science+Business Media, LLC, 233 Spring Street, New York, NY 10013, USA), except for brief excerpts in connection with reviews or scholarly analysis. Use in connection with any form of information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed is forbidden. The use in this publication of trade names, trademarks, service marks, and similar terms, even if they are not identified as such, is not to be taken as an expression of opinion as to whether or not they are subject to proprietary rights. 9 8 7 6 5 4 3 2 1 springer.com
Catheterization An implant procedure in which a small tube is inserted into a body cavity, duct, or vessel for the purpose of fluid administration or withdrawal ~ AALAS Reference Directory
Foreword In biomedical teaching and research, catheterizations of the jugular vein and the carotid artery have been used to access the cardiovascular system in various animal species. Such surgical procedures are technically challenging in rodents because of the small scale involved. There are not many alternatives if the rodent’s survival and easy post-operative handling are required. While rodents are becoming predominant research animals, reliable execution of these procedures is essential for many endeavors in pre-clinical research and product development. This practical guide should help scientists and technicians master the procedures in rats and thus confidently move forward to data collection. For those who have been fortunate to work with Angela Heiser in the laboratory, we have long witnessed how dedicated to the profession a researcher can be. Angie enjoys her work immensely. Her laboratory records are always focused, highly organized, and simply deduced but with in-depth knowledge. In addition to the sciences, she can add stunning, artistic impression to the content. No wonder I have seen so many superb presentations by Angie. Publication of this practical guide certainly will be a milestone. John H.K. Liu, Ph.D. Director, Molecular Pharmacology Hamilton Glaucoma Center University of California, San Diego La Jolla, California
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Acknowledgments Thanks to my mentors, Drs. John H.K. Liu & Arthur Lage, without whom I would not have been inspired or prepared for this adventure. Thanks to my husband and children for their patience. Thanks to Adria, Jane, Caroline, and Ami for constructive reviews. Thanks to many supporters who encouraged my confidence in this project and the field of animal science, especially Sally Ann. Thanks to Dave at Leica for the generous loan of camera equipment and to Nancy at Scion Pharmaceuticals for the use of their laboratory space. Thanks especially to Jenn for lending a hand when I needed one and to Dr. Lage for his unwavering and continued support.
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Table of Contents 1
Introduction
36
Instruments
3
Perioperative Care (Pre-operative care, Intra-operative care, Postoperative care, Pain, Record keeping)
37
Jugular Vein Catheterization
49
Carotid Artery Catheterization
7
Anesthesia (Ketamine cocktail recipe, Dosage chart, Stages of anesthesia, Reflexes, Rationale for ketamine, Weight considerations)
66
Blood Drawing Via Carotid Catheter (Maximum Volumes, Troubleshooting, Administration Volumes)
71
Research Applications
15
Aseptic Technique 76
20
Posture and Muscle Tremor
Rat Biodata (General, Reproductive, Cardiovascular, Metabolic, Brain, Clinical Chemistry, Spatial Definitions)
22
Surgeon’s Friction Knot 83
Latin Terms
24
Hemostasis Techniques 85
26
Catheters (Materials, Fill solutions, Stoppers)
Resources (Vendors, Websites)
91
Glossary
29
Anatomy (General dissection, Vessel anatomy, Unilateral carotid occlusion, Vagus)
98
Bibliography
34
Practice Surgery (PracticePak, Rat model, Cadaver, Non-survival)
110
Biography
111
Index
xi
Introduction
Jugular vein and carotid artery catheterizations are among the most widely used surgeries in research labs around the world. Typically, technicians teach these skills to incoming employees and move on to graduate studies or other fields. A resulting “oral history” of catheterization has been passed down from technician to technician. I have endeavored to capture these techniques on paper. Through the years, I have searched for and collected a number of training materials and guides for teaching purposes. This is my attempt to compile all the necessary information in one source. These catheterizations are extremely important for confirmed intravenous delivery of test substances and arterial blood collection. Catheterization reduces the stress of multiple sampling as observed in association with tail vein or orbital sinus techniques (Ling, 2003; Flynn, 1988; Cocchetto, 1983). Very few adverse effects, including a possible rise of corticosterones and a decrease in platelets, are associated with indwelling catheters except under chronic conditions (Fagin, 1983; Richman, 1980). With practice and dedication to research and humane animal use, one may develop a high throughput paradigm generating predictable results with what is generally
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thought to be a laborious, rate-limiting step in research. Counting thousands of catheterizations performed in my career, my survival and patency rate are 97%. “We refer to the art of surgery, so why not make it an art and, like the artist, be engrossed in its handicraft.” ~ S. Bunnell, Surgery of the Hand, 1944.
Some artists have argued that there is an element of science to their approach. I have discovered that surgery also involves an element of art. In fact, in 2004, UCLA organized an exhibit presenting “the world of nanoscience through a participatory aesthetic experience” (nano.arts.ucla.edu). From this basic guide, surgeons will evolve their own subtleties and personal preferences. My sincere hope is that this guide will secure knowledge for future generations of researchers in an original, undiluted format. Society demands a lot from science and this is my contribution. ~ Angie Heiser
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Perioperative Care Perioperative care includes pre-operative, intra-operative, and post-operative care of the patient. Careful attention to these areas is crucial to successful surgery. The goal of this section is to illuminate and define these often-overlooked components of the surgical process. Pre-operative Care (prior to surgery) Quarantine: Acclimate incoming rats to their new environment and housing for a minimum of 24 hours. It is preferable to quarantine for 7 – 14 days. This “grace period” allows the animal to return to normal hormonal and metabolic parameters as evidenced by stable body weight following the stress of transport. The investigator can determine that the animals are free of latent or enzootic diseases. Regular handling promotes less stress to the animal and leads to a quicker recovery. Pre-operative body weight: Weigh pre-surgery since rats are likely to experience weight loss post-surgery. Gross physical exam: Observe the animal for nose or eye discharge, diarrhea, fur matting, and overall appearance and behavior. Palpate for any growths, tumors, or skin abnormalities. Antibiotic: If antibiotics are preferred, it is most effective to administer prior to surgery in order to maximize blood levels during surgery and recovery. Pre-analgesic: Benefits of analgesics administered pre-surgery are many fold. Rats are less likely to exhibit depression in food intake or experience pain post-surgery and require lower injectable anesthetic doses during surgery. These combined factors contribute to a
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quicker recovery and fewer side effects. Single doses are recommended of one of the following; (1) IM or SC flunixin (flunixamine, banamine) @ 1.1 – 3.3 mg/Kg (Stewart, 2003), (2) SC or IV buprenorphine @ 0.01 – 0.05 mg/Kg (Hayes, 1998; Colletti, personal experience). Fasting: Do not withhold food prior to surgery unless absolutely necessary because the rat is not likely to consume much post-surgery. An empty stomach prior to surgery is not required since rats are a non-vomiting species (Takeda, 1993). Intra-operative Care (during surgery) Mucous membranes: Check the color of the eyes and tongue as an oxygen indicator. A blue color indicates possible hypoxia. Body temperature: Body temperature can be monitored. It is important to maintain body heat using a heating pad, heat lamp, or isothermic pad. Total blood volume: Avoid hypovolemic shock by controlling blood loss through good hemostasis during surgery. Body position: Use care to position the animal in the best possible way to protect cardiac and respiratory function. Respiration rate: Watch the animal’s breathing by observing the rise and fall of the chest. Observe the pattern and depth of breathing. During surgery, it is possible to monitor by noting the pulse in the carotid artery and the color of the blood in the artery through the scope. Tissue handling: Take care to handle tissues gently causing as little disruption as possible. Using a retractor instead of clamped hemostats reduces trauma to skin.
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Wound closure: The use of wound clips or subcuticular suturing may reduce self-mutilation during recovery. Post-operative Care (after surgery) Atropine: Atropine sulphate (parasympatholytic) is often used to counteract decreased heart rate due to increased vagal tone. In addition, atropine is used to decrease salivation; allowing the airway to stay open. The surgeon may prefer to administer atropine immediately after surgery to avoid bleeding complications from atropine’s effect of increased heart rate. The accepted dose is 0.05 mg/ kg IP. Check expiration date and make fresh. Anesthetic recovery: Before the animal is fully awake, emergencies can occur quickly and unexpectedly. This period of recovery requires the most frequent observation. The animal should be rotated every 30 minutes to avoid edema and irregular breathing. Keep the animal warm. Be careful to avoid heating pad burns from a high heat setting. Regulated heat sources are commercially available such as the ThermoCare ICU unit. Check the wound site for any bleeding. Acute recovery: This is a period during which the animal has resumed food and water intake and is approaching normal physiological parameters. The animal should have easy access to food and water. Transgel® or HydroGel™ are effective water sources and can be left on the floor of the homecage with rat chow or Nutra-Gel (food & water source). Individual housing: Rats should be housed one to each cage post-surgery. Catheters are better protected from cage mate curiosity and chewing. Some facilities may require this
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justification for individual housing because it is normally a more stressful housing condition. Rats prefer group housing (Gentsch, 1982). Long-term recovery: During this last stage of recovery, the animal is exhibiting normal physical and behavioral parameters. Rats may be more susceptible to corneal injury following injectable anesthetics (Turner, 2005). Observe the wound site for bleeding, infection, edema, unraveled sutures, and self-mutilation. Sutures can be removed at 7 – 10 days post-surgery. Observations should include motor function and the quantity/quality of urine/feces. Monitor weight gain/loss. Signs of Pain Clinical observations of pain and stress in rats can include: guarding the wound site licking/biting/scratching wound vocalization rough hair coat/ decreased grooming red staining around eyes and nose (porphyrin) self-mutilation of wound immobility decrease in food/water intake decreased exploring and grooming restlessness reluctance to move increased respiration hunched posture
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Anesthesia Ketamine-Xylazine-Acepromazine Cocktail (Adapted from Williams, 1994) Injection volume: Female Sprague Dawley: Intramuscular (IM) 2.2 ml/kg volume, half injected to each thigh Male Sprague Dawley: Intramuscular (IM) 2.4 ml/kg volume, half injected to each thigh Final concentrations: Ketamine 32.4 mg/ml (71.3 mg/kg) Xylazine 2.4 mg/ml (5.2 mg/kg) Acepromazine 0.42 mg/ml (0.9 mg/kg) Recommended dose ranges (Baker, 1979): Ketamine 50 – 100 mg/kg IM, IP Xylazine 1 – 5 mg/kg IM, IP Acepromazine 2.5 mg/kg IM, IP This cocktail can be pre-mixed and stored from two weeks (Johns Hopkins University animal resources) to 6 months (Yale University animal resources) if prepared using sterile methods.
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Ketamine Cocktail Dosage Chart (Sprague Dawley Rats) Body Weight (g)
Male (ml)
Female (ml)
230 235 240 245 250 255 260 265 270 275 280 285 290 295 300 305 310 315 320
0.550 0.560 0.580 0.590 0.600 0.610 0.620 0.640 0.650 0.660 0.670 0.680 0.700 0.710 0.720 0.730 0.740 0.760 0.770
0.510 0.520 0.530 0.540 0.550 0.560 0.570 0.580 0.590 0.610 0.620 0.630 0.640 0.650 0.660 0.670 0.680 0.690 0.700
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Rationale for the use of Ketamine The goal of anesthesia is to depress the CNS and block the perception of pain. The requirements for reaching a surgical plane of anesthesia are muscle relaxation, absence of reflexes, analgesia, and loss of consciousness. There are numerous methods for achieving this goal. Most of these agents have an additive effect; when combined, less anesthetic is required. It is important to distinguish between these agents. A sedative (or tranquilizer) reduces tension or anxiety without affecting physical or mental capabilities. An analgesic is an agent which blocks sensation of pain in the conscious state while an anesthetic does so in the unconscious state. Many of these agents may have different degrees and combinations of the described effects. Ketamine cocktail consists of xylazine (a potent sedative and muscle relaxant with analgesic effects), acepromazine (a sedative and anti-emetic), and ketamine (an anesthetic). Note: Acepromazine has anti-emetic properties. However, rats cannot vomit. The incorporation of acepromazine allows for a smaller dose of anesthetic and promotes a smoother recovery due to long lasting sedation (several hours). Side effects include suppression of thermoregulation that can lead to hypothermia. Acepromazine is a phenothiazine compound that acts partially by blockage of dopamine receptors in the brain. Xylazine ( -2-adrenergic agonist) is a potent sedative that acts via CNS depression. Xylazine has a significant depressive effect on respiration. In addition, partial atrioventricular block causes a change in cardiac conductivity; thus, decreased heart rate. Its immobilization effects are mediated via inhibition of nerve impulse transmission. Hyperglycemia and diuresis can be side effects. Ketamine is a non-barbiturate dissociative anesthetic that produces effects of immobility and respiratory depression. These are characteristics of the surgical plane (Stage III, Plane 2) of anesthesia that is detailed in a following section.
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Ketamine is the author’s choice of anesthesia due to its fast, short action, ease of administration, and wide margin of safety. In humans, up to ten times a normal dose has resulted in a longer but complete recovery (Ketamine website). Injectable anesthetic allows for easy access to the head and neck area; eliminating the need for nose cones. Ketamine is highly lipid soluble with a large distribution to fat cells. The metabolism of ketamine is dependent on hepatic clearance. The anesthetic action of ketamine is caused by a disruption between the sensory cortex of the brain and the limbic association areas; hence, the term dissociative. The mode of action is thought to include blockage of NMDA (N-methyl-Daspartate) receptors and the subsequent release of excitatory neurotransmitters. Effects of ketamine include: cardiac output blood pressure and heart rate bronchodilation salivary secretion cerebral blood flow and pressure amnesia catalepsy open eyes normal pharyngeal/ laryngeal reflexes
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This cocktail should provide approximately 30 minutes of anesthesia and 60 – 150 minutes of sleep time in the male Sprague Dawley rat. Female rats lack the liver enzyme CYP3A1 and are unable to metabolize as quickly as the males can via CYP3A2. These are the analog equivalents to human CYP3A4; a primary metabolizing enzyme involved in elimination (Kato, 1982). As a result, the anesthesia time for females is the same while the sleep time is considerably longer at 120 – 150 minutes. (Flecknell, 1996, and personal observation). The effects of ketamine and xylazine can be reversed using 2-antagonists such as yohimbine, tolazoline, or atipamazole (Cruz, 1997; Johns Hopkins animal resources website). An important consideration is the acidic disposition of ketamine. The acid pH is an irritant which can cause soft tissue inflammation, necrosis, and swelling at high doses in rats (Smiler, 1990). This effect can be greatly alleviated when the final concentration is a diluted form and given as multiple injections with a small gauge needle into deep muscle. The author has experienced no complications with acute studies.
Weight Considerations for Surgery The author recommends a weight range of 230 – 320g (Sprague Dawley rats). Greater than 320g: Anesthesia distributes to fat cells where it can temporarily be stored before release into the bloodstream. The heavier rats will store more anesthetic and seem to not be affected. Boosting with small extra doses to extend the surgical plane time, leads to large amounts released into the bloodstream at once and possible overdose due to cumulative effects. Additional complications include difficult dissection through fatty layer, collateral bleeding from the larger sized vessels, and leakage around the catheter. It has been shown that obese rats
11
are more susceptible to infection possibly due to fewer T-cells and lower splenocyte response (Tanaka, 1998). Obese animals exhibit slower wound closure time due to lower wound collagen accumulation in the fat layer (Goodson, 1986; Singer, 1999). Smaller than 230g: Rats that are too small or young tend toward poorer survival and longer recovery time. Further complications include anesthetic overdose and small vessels to catheterize.
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Reflexes Absence of reflexes are essential to reaching surgical plane of anesthesia Pedal Withdrawal Reflex: Extend the hindlimb and pinch the web of skin between the toes causing the foot to withdraw. Tail Pinch Reflex: Pinch the tail with your fingernails causing the rat to flinch. Toe Pinch Reflex: Pinch the toe with your fingernails causing the rat to flinch. Ear Pinna Reflex: Touch the hairs inside the ear canal lightly causing the ear to flick. Palpebral Reflex: Touch the edge of the eyelid causing the rat to blink. Corneal Reflex: Lightly touch the edge of the cornea causing the rat to blink
Reprinted with permission of Johns Hopkins University All rights reserved
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Stages of Anesthesia Stage I
Definition Injection to loss of consciousness
Stage II
Excitatory stage
Stage III
Sleep stage
Plane 1
Light anesthesia
Plane 2
Medium anesthesia **Surgical plane**
Plane 3 Plane 4
Deep anesthesia Anesthetic overdose
Stage IV
Anesthetic Recovery
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Terminal stage
Symptom Normal respiration Normal heart rate Ability to vocalize Normal reflexes Delirium Exaggerated sensory responses Excitable activity Depressed respiration Depressed circulation Depressed muscle tone Absence of reflexes Regular pattern of breathing Irregular breathing Depressed heart rate Depressed blood pressure Strong pulse
Mechanism
Selective depression of higher inhibitory CNS centers
Mild medullary depression Spinal cord depression
Spinal cord depression Severe spinal cord depression Respiratory distress Cardiac distress Paralysis Sternal recumbancy Reflexes return in reverse order
Aseptic Technique Good surgical technique includes minimal tissue disruption and dissection, minimal incision, use of appropriate instruments/suture material, minimal bleeding, and asepsis. Aseptic technique is used in survival surgery to limit microbial contamination. Distinctions and separations are made between “clean” and “dirty” items/areas. “Clean” includes sterile, disinfected, and sanitized. “Dirty” means contaminated. The importance of this technique lies in preventing post-surgical infection and, thus, minimizing potential pain and distress during recovery. It will, additionally, prove advantageous in reducing abnormalities and experimental variability in subsequent studies. The procedures outlined here are recommended minimum requirements. There is ongoing concern and debate over the necessity for aseptic technique in rodent surgery (Cooper, 2000). Surgeons may adapt this technique to better suit their particular circumstances. The Guide for the Care and Use of Laboratory Animals (1996) states that “some characteristics of common laboratory-rodent surgery” such as “ smaller incision sites, fewer people in the surgical team, manipulation of multiple animals at one sitting, and briefer procedures can make modifications in standard aseptic techniques necessary or desirable”. However, care must be taken to retain the basic fundamentals. The Animal Welfare Act requires consultation with your institutional veterinarian when planning studies that may cause pain, such as surgery. The veterinarian is an excellent resource when checking that your degree of aseptic technique is appropriate and meaningful. The National Institutes of Health (NIH) provide a detailed description of disinfectants used for survival surgery (oacu.od.nih.gov/ARAC/surguide.pdf).
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Site Preparation Initial consideration is to select the proper area for surgery. For the purpose of rodent surgery, this should be a dedicated area, which has little to no traffic and is separate from the study area. There should, in fact, be separate areas for animal preparation, surgery, holding and recovery, and euthanasia.
Materials Clean lab coat, disposable jacket or clean scrub shirt Bench paper, underpads Glass bead sterilizer Disinfectant Clippers Ophthalmic ointment (Paralube) Clean or sterile gloves Face mask 70% isopropyl alcohol Antiseptic scrub (betadine) Antibiotic (verify expiration date) Reprinted with permission from Johns Hopkins University Sterile drapes (See pictures) All rights reserved
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Instrument/Catheter Preparation and Sterilization Methods I.
II. III.
IV.
Glass bead sterilizer: Glass beads are heated to approximately 450°F. Instrument tips are heated at this temperature for 15 seconds. Only the tips are sterilized and placed on the sterile drape or paper. This is useful when performing multiple surgeries. Do not begin surgery while instruments are hot. Only heat clean instruments to avoid buildup of blood and to properly sterilize the entire surface of the instrument tip. Autoclave: Instruments, gauze, drapes, suture material, and cotton swabs can be autoclaved. Sterilization is accomplished by steam at 250°F and 15 PSI for 30 minutes. Gas sterilization: This is accomplished by ethylene oxide and is useful for catheters derived from polyethylene or silicon tubing. This process takes 8-10 hours. Several days may be required to dispel the toxic gas before use in surgery. Disinfectant: These include sporocidin, cidex, and sonacide in which instruments and catheters are immersed for 10 hours @ room temperature in a 1:10 diluted solution. Cidex (3.4% glutaraldehyde) is highly recommended for catheters because it rapidly and easily disinfects surfaces. The Cidex solution expires 28 days after dilution and should be labeled. Catheters should be flushed well with sterile saline. Instruments should be wiped with sterile saline or water prior to use. Clidox and novalsan should be used according to label instructions.
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Rat Preparation
I.
Hair removal: Hair should be shaved as close to the skin as possible by clippers. Remove all loose hair by vacuum or tape. The rule of thumb is to expose an area that is twice the area needed for incision. A close shave can be best accomplished using appropriate tension on the skin and shaving counter-direction to hair growth as shown below.
II.
Cornea protection: Use a small portion of ophthalmic ointment, such as paralube, on the eyes. The eyes stay open and can dry out causing damage to the cornea. This will be evidenced by a white discoloration of the cornea post-surgery (Loger, 1997). Skin preparation: Start in the center and in a circular motion outwards, swab the skin with betadine. Follow with a 70% isopropyl alcohol swab. Repeat these steps twice more. Incision preparation: When the rat is secured properly on a clean surface, cover the surgical area with a sterile drape to create a barrier to the incision. Position a hole in the drape over the incision site. One may also use sterile gauze to create a barrier between the surgical area and the rest of the body.
III.
IV.
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Surgeon’s Attire The surgeon should wear a clean lab coat, disposable jacket, or clean scrub shirt. Wash hands thoroughly with a disinfectant soap. One may wear a clean, fresh pair of lab gloves or sterile gloves. Handling of instruments is easier with a fairly snug fit of gloves. A facemask will help protect the surgeon from reactions to rodent allergens. Once the surgeon, surgical area, and rat are prepared, one must remain conscious throughout the procedure not to break the aseptic barrier that has been created.
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Posture and Muscle Tremor Correct body posture is extremely important to consider when performing surgery. The surgeon may be required to spend hours in this position each day. Outlined here are some simple recommendations that will help you avoid back and neck pain, muscle fatigue, and muscle tremor. Minute tremors of the hand are greatly amplified through the dissecting scope making accurate, coordinated movements difficult to complete. 1) A well-rested surgeon is best prepared. Weight lifting and coffee drinking before surgery are discouraged since they can exaggerate muscle tremor.
© Grimmy, Inc. Reprinted with special permission of King Features Syndicate
2) Sit in a comfortable lab chair with adjustable back support and adjustable height. Hydraulic tables are commercially available from Boston Tec. The spine along your back and neck should be straight. Both feet should be on the ground slightly apart. A footstool can accomplish this for tall chairs. 3) Adjust the dissecting scope such that your eyes are looking straight ahead and your neck is not bent.
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4) Adjust the individual eyepieces to optimize visual clarity and reduce eyestrain. Close one eye and adjust eyepiece to focus clearly. Repeat with other eye. Then use fine focus with both eyes open. Some dissecting scopes allow one to focus without the use of glasses. 5) Rest forearms and elbows on the surgical table. 6) Support the wrists with paper towels or rolled up washcloths to steady the hand. The wrist should always be straight and not flexed. This will allow blood flow and nerve conduction to remain unimpeded. If you experience tingling or numbness in your fingers, drop them below your waist and shake your hand until it goes away. Readjust your hand/wrist position. Remove watches, bracelets, and rings for optimum support and comfort. 7) Do not hold your breath or hyperventilate. Take a deep breath every so often. 8) A radio playing softly in the background can be useful in creating white noise and thereby increasing your concentration by blocking out general and sudden lab sounds. 10) Take a break every 30 – 60 minutes. Stand up, walk around, and stretch.
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Surgeon’s Friction Knot
22
1. Use PracticePak
2. Throw 2 loops & grasp other end
3. Pull through & tighten firmly
4. Throw 1 loop & grasp other end
5. Pull through
6. Tighten firmly. The knot is tight enough when no light can be seen through the hole. Tightening too much will constrict blood flow through the catheter.
23
Hemostasis Techniques One may employ a number of techniques in order to ensure hemostasis during surgery. Hemostasis is the state of zero blood loss and normal volume in the closed circulatory system. Minimal blood loss during surgery is directly related to increased survival rate. Many factors can contribute to minimal blood loss such as body temperature, blood pressure, ventilation, patient position, and small incision/dissection. Hypothermic patients tend to lose more blood and use more oxygen. Anesthesia lowers blood pressure, which will slow blood loss. Administration of oxygen during surgery (hyperoxic ventilation) will boost the blood oxygen to vital organs following blood loss. Several methods for stemming blood loss following incision and dissection include: Pressure – use sterile gauze or cotton applicators to apply pressure until platelet formation has stopped bleeding. Clamp – use hemostat, forcep, or vessel clip to clamp at the source of bleeding. Heat – one may use a sterile or disposable cautery to apply heat in order to coagulate blood. Recent tools and techniques used in human surgery to control blood loss may be available soon for rodent survival surgery. Coagulating tools include an argon beam plasma coagulator (argon gas and high frequency electrical current), harmonic scalpel (ultrasound waves), and gamma knife (radiation). In addition, laser and cryosurgery techniques minimize blood loss (www.adam.com, Strategies and techniques during surgery). In the case of severe blood loss, replacement fluids may be given intravenously to maintain fluid volume. In humans,
24
following blood donation of one pint (10% blood volume), fluid volume is replaced within 24 hours. Red blood cells, however, may take up to two months to be replenished (www.aabb.org).
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Catheters Several types of biocompatible materials are currently used for catheters. Despite this compatibility, infections and blood clots can occur. Infections are primarily caused by catheters contaminated with skin microbes during insertion or the fill solution of the catheter (Goldmann, 1993). Fill solution The fill solution usually consists of heparinized saline @ 10 – 1000 IU/mL due to ease of formulation. A heparinized hypertonic glucose solution is an alternative to the use of saline (Mann, 1987). The more viscous additive of heparinized PVPD (polyvinyl pyrrolidone) prevents blood clots and back up of blood into catheter. It is, however, more difficult to handle. Heparinized glycerol is quite viscous though claiming the best patency for long-term applications (Luo, 2000). Heparin-coated catheters have had proven patency of up to 30 days (Foley, 2002). Stoppers Stoppers (or obturators) usually consist of wax, nylon filament (fishing line), or stainless steel wire. Bone wax is easier and faster to use while collecting blood. The wax can melt if care is not taken during recovery near a heat source. A solid obturator requires some practice and coordination for quick and efficient use. Polyethylene catheters Polyethylene (PE) is the most common catheter material. The use of PE gained popularity following the publication of the Tinsley study in
26
1983. PE tubing is available in many sizes. Its rigidity helps to prevent twisting/crimping postimplantation and diffusion permeability through the walls. The author prefers this material due to the ease of construction. It is best used for acute studies because it is susceptible to thrombin clots with long term use. It is of note to consider that polyethylene tubing contains toxicants called phthalates. These plasticizers provide characteristics of flexibility and strength but can be absorbed by the animal during longer-term studies. Studies of phthalates in rats report hyperactive thyroid gland following exposure for three months (Price, 1988). Silicon catheters Silicon (silastic®) tubing is less likely to form clots. However, the flexibility allows for twisting/crimping post-implantation and can lead to loss of compound as it is absorbed into the walls. The walls will expand easily which can be problematic when attached to continuous infusion pumps, blood pressure apparatus, or automatic blood sampling devices. Correct blood pressure values may not be reflected as a result. Silicon tubing is a good choice of material when using solvents in the vehicle. In general, its inert properties reduce possible vehicle reactions with the tubing material. Hybrid catheters Today, it has been shown that hybrid catheters can combine the best attributes of both materials. Silicon is used for implantation while connected to PE tubing for extravasation. These catheters can be laborious to construct and sterilize. They are most advantageous for use in long-term studies and have demonstrated patency for up to two weeks (Arlund, 1997).
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Alternative materials Many companies now offer customized pre-constructed catheters. Braintree Scientific carries a catheter made from a perflourocarbon material which is reported to cause less nerve damage when implanted intrathecally (Sakura, 1996). Other catheter materials include polyvinyl (Tygon®) and polyurethane (Renathane®) which can provide flexibility using natural elastomers. Investigate the possibility of absorption of vehicle and compounds with any delivered fluid. Catheter Preparation (250g rat) The 12” carotid artery catheter is marked at 24 mm from the end with a permanent marker. The 12” jugular vein catheter is marked at 12 mm from the implanted end. Make sure the ends of the catheters are cleanly cut without any remaining bevel or jagged edge to avoid unintentional puncture of the vessel walls. Keep a hemostat on the carotid catheter until ready to flush back. Do not allow jugular catheter to fall below table height. Gravity will cause blood to escape even with low venous pressure.
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Anatomy General Dissection Figure 1 displays the underlying musculature. Figure 2 demonstrates the complex in situ anatomy of the vessels in the neck of the rat. These figures should assist in the gross dissection and location of the carotid artery and jugular vein.
(reflected) Sternohyoid muscle
Omohyoid muscle
Separate muscles here to locate underlying carotid artery
Figure 1
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External carotid artery Internal carotid artery
Common carotid artery External jugular vein
Internal jugular vein
Aortic arch
Atria Vena cava
Figure 2 Ventricle
30
Vessel Anatomy (Carolina Biological Supply Company, Picture used with permission) The differences between arteries and veins can be described as such: Arteries are more flexible and carry blood away from the heart at relatively high pressure. Veins are less flexible due to fewer elastic fibers and contain semi-lunar valves which allow blood to flow only towards the heart at a lower pressure. Blood vessels, with the exception of capillaries, contain three distinct layers in the vessel wall. The innermost layer in all vessels is the tunica intima or endothelium. Endothelium cells can detect pressure, oxygen, and flow changes. They have the ability to affect vascular smooth muscle tone. Oxygen is obtained by diffusion from red blood cells in this layer. The middle layer consists of smooth muscle and autonomic nerves. It is referred to as the tunica media. This layer is very elastic and mostly in arteries. The outermost layer, called tunica adventia, is the most prominent in veins. It is comprised of primarily collagen, some smooth muscle, and autonomic nerves. One must be mindful of these properties when manipulating the carotid artery and jugular vein. Excessive handling can cause vaso-constriction and shredding of the vessel walls. The more delicate, fibrous layers of the jugular vein can separate making insertion of the catheter difficult and frustrating. Care must be taken in the placement and location of the catheter. Waynforth and Flecknell (1992) describe the descending aortic arch and the entrance to the right atrium as the optimum placement for the carotid and jugular catheters, respectively. The author prefers a more distal placement to the heart to accommodate the variability in body size. The distance of insertion should be adjusted to body size (1 cm/100g BW) if the Waynforth placement is desired.
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Unilateral Carotid Occlusion: Blood Flow
Anterior cerebral arteries Anterior communicating artery
Internal carotid artery
Posterior communicating artery
Circle of Willis
Basilar artery
Vertebral arteries
32
Middle cerebral artery
The carotid and vertebral arteries on both sides of the body provide the blood supply to the brain. The circulation from both sides is connected by the circle of willis in the brain. The circle of willis allows both sides of the brain and body to maintain pressure equilibrium. Collateral circulation to other organs travels from the carotid via the ipsilateral pterygopalatine, superior thyroid, and occipital arteries (Smith, 1996). In humans, these connecting vessels have too small a diameter to maintain adequate blood supply following unilateral carotid occlusion. In many other mammals, the anterior and posterior communicating vessels are abnormal or missing. Gerbils have unique anatomy; up to one third have no anterior communicating vessels. These animals experience severe stroke when a unilateral carotid occlusion is performed (Davson, 1996). The rat communicating vessels are present and can carry sufficient supply of blood to prevent stroke when unilateral carotid occlusion is performed. In addition, rats have been shown to develop extra collaterals when the carotid is chronically occluded (Coyle, 1990).
Vagus Presentation In a normal presentation, the vagus nerve runs parallel to the carotid artery for the length exposed.
In a crossover presentation, the vagus nerve crosses the carotid artery at unpredictable locations.
Choose your suture placement carefully to avoid possible trauma and damage to the vagus nerve caused by friction against the suture material. Vagal stimulation can result in cardiac abnormalities or failure.
33
Practice Surgery “Retrospective reviews ... clearly indicate that operative experience is the single most critical factor related to improved success rates. Surgeons with a high success rate went through a learning curve, and most of them still learn from occasional complications. They improve by learning what they … realized through hindsight to be a mistake.” ~ Khouri, 1992 “The difference between one experimenter’s success with a technique and another’s failure may have as much to do with differences in the experimenter’s skill as with any flaws inherent in the technique.” ~ Giner, 1987
PracticePak Practice Practice suture techniques, knot tying, or getting used to microscopic surgery and posture using a Sharpoint suture pak. This pak is designed by Surgical Specialties to resemble the texture of skin and is invaluable for orienting the surgeon before using live animals or cadavers.
Rat Model Practice Microsurgical Developments PVC-Rat from Braintree Scientific is useful for practice of both catheterizations. Cadaver Practice It is advisable to use a rat cadaver prior to using a live animal. Cadavers will assist in the orientation of the anatomy and insertion of the catheter without the complication of blood pressure.
34
Non-survival Practice The final step for the beginner is to try a live animal, under a more experienced surgeon’s supervision, and sacrifice the rat before recovery from anesthetic. This is an excellent way to practice and reduce the time in which a catheterization can be performed. Ketamine cocktail can be boosted 100μl every 30 minutes. Several drops of lidocaine on the artery can reduce vasospasms and vasoconstriction, which are evident following the excessive manipulation during practice surgeries. Less procedure time will decrease the stress to the rat and reduce recovery time. The first few jugular and carotid catheterizations will generally take 30 – 60 minutes per rat. The average time in which a proficient surgeon should be able to complete the two procedures is 12 – 15 minutes per rat.
35
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Instruments
Wound clips Wound clip applicator
Bone wax Vessel clip
Two mosquito hemostats
Scalpel handle & blade
retractor
Vannas microscissors Two straight forceps One curved forceps
36
Jugular Vein Catheterization Note: In the following pictures, the incision size is larger and drapes are absent for a clearer presentation
37
Materials
Procedure
Scale Gloves Permanent marker
Put on gloves. Weigh rat & record. Mark rat ID# on base of tail.
Decapicone
Restraint
(insulin syringe+28G½ needle) Ketamine Cocktail:
IM injection @
Ketamine
2.2 –2.4 ml/kg half each thigh using restraint.
Xylazine Acepromazine Sterile Saline
Heating pad
38
Maintain body heat before, during, & after surgery on low setting.
Pictorial
Materials
Procedure
Hot bead sterilizer Instruments Sterile towel
Sterilize instruments.
Clippers
Surgical board Tape Gauze bolster: Roll up two pieces of 3”x3” gauze and tape together
Pictorial
Note: Sterilize towels, gauze, wound clips, sutures & cotton applicators
Shave hair on anterior upper thorax (A) & over scapula (B).
In dorsal recumbent position, secure forelimbs with tape. Place bolster under neck. to clear airway, pull out tongue to side. Check reflexes.
(A)
(B)
39
Materials
Procedure
Betadine pad Alcohol pad
Wipe betadine in concentric circle from middle to outside. Wipe with alcohol pad. Repeat twice more. Wipe scalpel blade with used pad (heat dulls blade).
Pictorial
Drape incision site. Sterile drape or 3”x3” sterile gauze
No. 4 scalpel handle & No.22 blade
Make 2 – 3 cm midline skin incision while stretching skin to create tension.
Sterile 3” x 3” gauze Sterile cotton Applicator
Stop any bleeding.
40
Note: If catheterizing only the jugular vein, make a smaller incision closer to the vein
Materials
Procedure
Straight forcep Mosquito hemostat
Locate rat’s left Jugular vein by lifting up skin with forcep & separate from fat layer with hemostat using a scissors action.
Pictorial
Note: Hemostat can be used to retract skin. Reduce trauma if possible.
Observe the exposed jugular vein. Straight forcep Curved forcep
Grab connective tissue at anterior end with straight forceps (1). Using the curved forceps (2) in a scissors action, make small pocket on each side of the jugular.
1
2 Anterior 41
Materials
Procedure
Straight Forcep Curved forcep
Place closed curved forcep (2) parallel to jugular vein, point downwards, & then point it perpendicular to the vein & push underneath.
Sterile 6-inch silk suture
Open forceps, grab the suture & pull back through. Throw two loops & pull tightly.
Throw one loop in other direction & pull tightly.
42
Pictorial
2
2
Materials
Procedure
Mosquito hemostat
Attach hemostat to loose ends for tension.
Straight forcep Curved forcep
Use forceps to make pockets at posterior end of exposed vein.
Pictorial
Posterior
Carefully push curved forcep underneath avoiding puncture of vein.
43
Materials
Procedure
Sterile 6-inch suture Mosquito hemostat
Pull another suture length through. Throw two loops loosely & attach hemostat to apply tension (A). Do not tie off.
Straight forcep Curved forcep
Use forceps to make pockets at middle of exposed vein.
Straight forcep Curved forcep
Push curved forcep underneath. Use straight forcep to reflect skin.
44
Pictorial
A Tip: Keep loose suture end taut while pulling through to reduce friction to vein
Materials
Procedure
Sterile 6-inch suture
Grab suture length & pull through without any loops or ties.
Vannas microscissors
Make small “V” cut (venotomy) into top of vein. Tension on the posterior suture should prevent blood flow. Increase tension if necessary.
Pictorial
Posterior
Observe opening.
45
Materials
Procedure
Two straight forceps 12 inch PE50 (marked @ 12mm with marker) attached to 22½G needle on 10 mL syringe filled with 100IU heparinized saline
Lift up flap of “v” to open hole for easier insertion.
Insert blunt tipped catheter into hole until mark is at the hole.
Observe location.
46
Pictorial
Materials
Procedure
Two straight forceps
Tie off suture (1) with surgeon’s knot to secure venotomy site.
Pictorial
1
Keep sutures straight to avoid confusion while tying off. Tie off suture (2) with additional throw in opposite direction.
2
Tie off suture (3) to secure vein to catheter as anchor. Three sutures provide superior security. 3 47
Materials
Procedure
Large Scissors
Cut extra length off. Do not cut too short to avoid unraveling. Do not leave too long to avoid wicking.
10cc syringe filled with 100IU heparin/ ml saline
Check success by withdrawing blood & then flush back. Make sure catheter is clear of blood to avoid clots.
Sterile bone wax
Remove tubing from needle & plug with sterile bone wax.
48
Pictorial
Carotid Artery Catheterization Note: One may catheterize the carotid artery following the jugular vein catheterization OR catheterize the carotid artery only. For carotid only, follow the preparatory steps outlined for the jugular catheterization and make a smaller midline incision.
49
Materials
Procedure
Mosquito hemostat Straight forcep
Locate omohyoid muscles. Reflect salivary glands to side. With scissors action of hemostat, separate right omohyoid from the sternohyoid muscle.
Pictorial
(Jugular vein catheter is to the left)
Use forceps to provide tension, if necessary, to expose the common carotid artery.
50
Materials
Procedure
Pictorial Note: Avoid puncture of esophagus or trachea with retractor
Retractor in closed position
Insert and open retractor to secure clear view of right common carotid artery. Check respiration due to pressure on trachea.
#5 straight forcep Vannas microscissors
Cut away any ragged edges to clear view.
Lift remaining muscle away from artery and carefully transect.
51
Materials
Procedure
Curved forceps Straight forceps
Grab connective tissue at anterior end with straight forceps & pull away slightly from carotid to locate the vagus nerve.
Pictorial Vagus
Anterior
Using the curved forceps in a scissors action, make small pocket between the artery & nerve, posterior to the bifurcation of exterior & interior carotid, without touching the vagus.
52
Note: Do not touch vagus nerve. It controls breathing. The recovered rat will gasp. The sympathetic nerve controls pupil size. If cut, the recovered rat will squint in that eye.
Posterior
Vagus
Materials
Procedure
Curved forceps Straight forceps
Place closed curved forcep parallel to the middle of the carotid, point downwards into pocket, & then point it perpendicular to the artery & push underneath.
Sterile 6-inch suture
Open forceps, grab a suture length & pull back through.
Hemostat
Tie a surgeon’s knot & secure with hemostat to apply tension.
Pictorial
53
Materials
Procedure
Curved forceps Straight forceps
Use forceps to make pockets at middle between vagus & artery.
Push curved forcep underneath vessel taking care to not include vagus.
Sterile 6 inch suture
54
Pull another suture length through.
Pictorial
Materials
Procedure
Curved forceps Straight forceps
Throw two loops. Leave loose.
Pictorial
Tip: Keep suture lengths straight & untangled
Sterile 6-inch suture
Repeat pocket and loose suture at posterior end.
55
Materials
Procedure
Vessel clip Vannas Microscissors Two straight forceps
Place vessel clip into posterior pockets to stop blood flow from heart. Do not clip vagus. Use straight forcep to open pocket for clip.
12 inch PE50 marked @ 24mm with marker attached to 22 1 G needle on 10 mL syringe filled with 100IU heparinized saline – clamp catheter with hemostat at unmarked end to prevent blood flow
56
Make V-cut into top of artery between 2nd and 3rd posterior sutures. Some trapped blood will “pop” out. Coat drying vessel with this blood. Thread blunt catheter into hole up to clip.
Pictorial
Tip: Lift up flap of “V” with straight forceps creating a “tent” to thread catheter
Materials
Procedure
Two straight forceps
Hold forcep 1 around artery & catheter tightly just posterior to V-cut so no blood will escape. Remove clip.
Pictorial Posterior
1
Using forcep 2, push catheter into artery until mark is at posterior suture. 1
Vessel clip
While still holding artery closed with forcep 1 drop forcep 2 & quickly place vessel clip back in same place over catheter.
2
57
Materials
Procedure
Two straight forceps
Tie two posterior sutures & remove vessel clip. Tie anterior suture.
Scissors
Cut excess length.
Pictorial Posterior
Remove retractor.
Anterior 58
Materials
Procedure
Pictorial
Sterile bone wax
Unclamp hemostat from catheter end & withdraw blood to check success. Flush back until clear. Re-clamp & disconnect needle. Plug end with sterile bone wax. Unclamp hemostat.
Tip: Do not over flush. Excessive heparin will cause internal bleeding.
Scissors
Untape & turn rat onto side. Make small cut on back of neck.
59
Materials
Procedure
Hemostat
Staying close to the skin, insert closed hemostat @ back of neck & push through to ventral incision. Open hemostat & grab catheter. Pull jugular catheter through left side to back of neck. Pull carotid catheter through right side to back of neck. The trachea should not be crossed.
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Pictorial
Materials Wound clips Wound clip applier
Procedure Pull skin edges together under neck.
Pictorial Tip: Hold skin up & away from catheter when applying wound clip to avoid puncture of the catheter.
Apply wound clips to skin about every cm.
61
Materials
Procedure
Vetbond
Use one drop of vetbond in between wound clips & press edges of skin together to seal wound.
Marker
Hemostat
62
Flip over rat to sternal recumbent position. Use marker to identify jugular vein catheter @ end.
With scissors action, create large pocket posterior to hole.
Pictorial
Materials
Procedure Coil excess catheter lengths separately & tuck into pocket.
Wound clips Wound clip applier
Pictorial Tip: Do not bend catheter while coiling. It will prevent any subsequent blood flow.
Lift skin & two catheters (in opposite directions) & secure with one wound clip.
63
Materials
Procedure
Wound clips
Do not allow wound clip to puncture catheter inside pocket.
Wound clip applier
Tip: For studies longer than 24 hours, one may tuck carotid catheter end back through clip for added security.
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Pictorial
Materials
Procedure
Pictorial
0.1 mg/mL Atropine sulphate
Administer IP injection of 0.3 mL atropine sulphate to block vagal stimulation. Place anesthetized rat on side on heating pad (low) until able to right self. Change sides every 15 – 30 minutes. Place rat in cage with transgel & food on bottom of cage. Singly house rats to prevent chewing of each others’ catheters. Allow minimum of 1724 hours recovery before use in study.
Note: Post-operative pain management is recommended unless there is scientific evidence that it will interfere with studies such as pharmacokinetics and CNS models.
Heating pad
Transgel® Rodent chow Rodent cage
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Blood drawing via carotid catheter It is generally agreed among experts that 10% or less of the circulating blood volume can be removed without resulting gross abnormalities. With this amount of blood loss, baroreceptorinitiated reflexes can cause a release of cholinergics from the medulla and sympathetic nerve endings. Increased heart rate results from constricted arteriole beds and venous reservoirs in the muscle and skin. There is a minimal effect on blood pressure and cardiac output. The slow rate of blood volume replacement is caused by a secretion of antidiuretic hormone and activation of the renin-angiotensin system (ILAR, 1989). Blood volume of a rat is 58 – 70 ml/kg (Diehl, 2001). If we base our calculations on the midpoint of the range (64 ml/kg), a rat weighing between 225 – 320g would have a blood volume of 14.4 – 20.5 mL; therefore 1.4 – 2.1 mL can be withdrawn safely. The formula for chronic, repeated blood sampling is 0.6 ml/kg/day (Joint Working Group, Lab Animals, 1993). Cardiac output and blood pressure are depressed at 15 – 20% blood loss. A massive cholinergic release leads to tachycardia and compensatory tachypnea. Extreme arteriole constriction redistributes blood away from the gut and skin. It is reported that 20% blood loss can cause a 25% reduction in arterial pressure (Ploucha, 1986). Lower oxygen levels produce anaerobic glycolysis. Increased plasma lactate produces metabolic acidosis. Venous constriction helps to maintain venous return. Finally, interstitial fluid is transported to intravascular compartments; helping to slowly replace fluid volume. In humans, this vasovagal response produces clinical signs of nausea, dizziness, and blurred vision (ILAR, 1989). If one withdraws 30 – 40%, hemorrhagic shock is possible. In addition to tissue anoxia, hypercapnia, and acidosis, a poorly perfused pancreas depresses myocardial function. This cascades into cell injury, irreversible tissue damage, organ failure, and death. Poor blood flow
66
in the medulla reduces any compensatory reflexes (ILAR, 1989). Hematocrit values may not be accurate in the 72 hours following blood loss due to a proportional RBC: plasma reduction (Wintrobe, 1981). More than 40% total blood removal can result in mortality of half the number of rats used. Blood volumes should not be removed too frequently or too rapidly. Even small volumes in this manner can lead to acute shock or anemia. For required intensive blood sampling in 8 – 24 hour pharmacokinetic studies, it is acceptable to remove up to 20%. The rat should be sacrificed at the terminal bleed. It is reported that extreme loss of blood can induce feelings of anxiety and disorientation and it is considered inhumane and unethical in the treatment of laboratory animals (AVMA Panel, 2000). Fluid replacement is acceptable with saline, ideally warmed at 30 - 35°C. Symptoms of anemia include pale color (eyes, ears, tongue, and extremities), decreased activity, and increased respiration rate when active. Symptoms of shock include dry membranes, low body temperature, restlessness, and hyperventilation.
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Troubleshooting blood drawing Several problems can be encountered when withdrawing blood from the carotid catheter. The following recommendations should assist you in obtaining blood samples with the least difficulty after catheterization. The rat should have a minimum of 17 – 24 hours to recover from surgery. Carefully restrain the rat in a broome restrainer or any restrainer with access to the catheter. The catheter can be pulled through the opening. Using your thumbnail or a hemostat, occlude the catheter while cutting off the plugged end with scissors. Release the hemostat or your thumbnail to collect free flowing blood. Flush back with heparinized saline (100 IU/ml saline) using 22-gauge needle and plug with obturator. Tuck excess catheter back into pocket after removing rat from restrainer. 1) Make sure the rat is relaxed and acclimated to restrainer. Stress can cause vasoconstriction. 2) A small clot could form at the implanted end of the catheter. Often this is a flap that allows injection but not withdrawal. One may try to gently withdraw first. Too much force will collapse the vessel. Next try short, quick bursts of injected heparinized saline to dislodge. 3) If the catheter was tucked in too far after surgery, it is possible that the exposed end will disappear into the pocket. Often the body temperature will cause the bone wax to melt and the rat will bleed to death. This is evidenced by a large hematoma at the back of the neck. This can be avoided by using solid obturators.
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4) Individual housing will keep fellow rats from chewing each other’s catheters. However, if the catheter is left out too far, the rat can reach it and chew by itself. The rat will bleed to death and blood is generally shaken all over the cage. 5) A rat left on the heating pad too long after surgery without proper supervision can cause the bone wax to melt and bleeding to occur. Again, solid obturators may be chosen to avoid this condition. 6) Make sure the catheter is not too tangled or crimped inside the pocket. If no blood flows and it is impossible to inject saline, this may be the case. You can try to pull out a generous length of catheter to check and tuck back in properly. 7) Due to increased blood pressure following surgery, there may be a small amount of blood in the implanted catheter end. Withdrawing gently with a syringe can dislodge clotted blood that has formed. 8) Do not over flush with heparinized saline. It can cause internal bleeding. 9) The catheter end can twist slightly at the point of insertion into the artery once the rat is recovered and in its normal position. Leaning against the vessel wall can block the implanted catheter end. It is possible to put your finger or a forcep into the restrainer and adjust the angled position of the neck by tipping the chin upward. 10) One may try to palpate the neck gently to regain blood flow. 11) To dislodge clots, one may insert a small wire into the catheter followed by gentle withdrawal by syringe to extract dislodged clot. 12) To maintain patency over several days, flush catheter daily.
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Recommended Administration Volumes Dose in feed
5 g/100 g/day
Dose in water
10 ml/100 g/day
Gavage
5 – 10 ml/kg
Intravenous
1 – 1.5 ml/kg
Continuous IV
1 ml/kg/hr
Intraperitoneal
10 – 30 ml/kg
Intraperitoneal injection placement
Intramuscular injection Placement
Subcutaneous
10 – 30 ml/kg
Intramuscular
1 ml/kg
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Research Applications Use of venous catherization The primary use of venous catheterization is for intravenous administration. This route is advantageous due to the predictability and reproducibility of drug kinetics. One is able to deliver agents in a controlled manner via pumps. Intravenous deliveries bypass the stomach and, therefore, avoid gastric pH and first pass metabolism issues. There is rapid onset at the target site. This is the route of choice for protein and peptide-based drugs. There are several considerations to note prior to intravenous delivery. One must be aware of possible vascular irritation and damage caused by the test substance, leakage out of the vessel, volume overload (hemodilution), hemolysis, and infection. One must also carefully consider the solubility and pH of the test substance. Solution should be 7.4 pH adjusted and completely soluble. Any particulates will cause an emboli. Methods in vascular infusion biotechnology in research with rodents by Dr. Nolan (2002) is an excellent resource for this application. Intravenous injections may be given as: Bolus – equal to or less than 20 seconds, may be given manually using a 22 gauge needle to connect to the jugular catheter Slow push – usually between 1 – 5 minutes, may be given manually or via pump Continuous infusion – usually hours to days to reach a steady state in the plasma, must be delivered via pump. The rat is fitted into a harness and the catheters threaded through a
71
protective sheath to an overhead swivel and infusion pump. Alternatively, an osmotic pump filled with test material can be implanted SC and attached to the catheter. Vendors of continuous infusion equipment: Instech Solomon 5209 Militia Hill Road Plymouth Meeting, PA 19462 800-443-4227 www.instechlabs.com Lomir Biomedical, Inc. 99 East Main Street Malone, New York 12953 518-483-7697 www.lomir.com Bioanalytical Systems, Inc. (BAS) 2701 Kent Avenue West Lafayette, Indiana 47906 www.bioanalytical.com
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Use of arterial catheterization The most common use for arterial catheterization is serial blood sampling. Catheterization of the carotid artery provides a sampling procedure, which has technical ease and greatly reduces stress to the rat. Other uses include CNS delivery and cardiac monitoring. Blood sampling – Serial sampling may be performed manually or via robotic samplers. Automatic blood samplers (ABS) provide many benefits including fluid replacement, less supervision, precise timepoints, and collection of inconvenient timepoints. Consider preparatory time, maintenance and cost required when choosing between manual and ABS methods. A combination of the two can be quite efficient and serve many purposes. Remember sampling volume criteria to avoid stress to the rat. Methods in vascular infusion biotechnology in research with rodents by Dr. Nolan (2002) is an excellent resource for this application. Intra-arterial administration – Reversing direction of the catheter insertion to a rostral placement, allows for delivery of test substances to the brain. Research in CNS indications, such as stroke and Alzheimer’s, benefit from this administration by directly reaching the brain without metabolism.
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Cardiac parameter monitoring – Carotid catheterization is useful for monitoring blood pressure, heart rate, ECG, temperature and blood gases. The catheter is attached to transducers outside or inside the body.
Vendors of ABS equipment: Instech Solomon 5209 Militia Hill Road Plymouth Meeting, PA 19462 800-443-4227 www.instechlabs.com Bioanalytical Systems, Inc. (Culex) 2701 Kent Avenue West Lafayette, Indiana 47906 www.bioanalytical.com DiLab Inc. 11 Goldsmith Street Littleton, MA 01460 888-844-3633 www.dilab.com
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Vendors of blood pressure equipment: ADInstruments 2205 Executive Circle Colorado Springs, CO 80906 719-576-3970 www.adinstruments.com Data Sciences International (DSI) 4211 Lexington Avenue, North, Suite 2244 St. Paul, MN 55126 800-262-9687 www.datasci.com
Mini Mitter 20300 Empire Avenue, Bldg B-3 Bend, OR 97701 800-685-2999 www.minimitter.com
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Kidneys Liver Lung Spleen 9Total Body Water 9Intracellular Fluid 9Extracellular Fluid Growth Rate
Rat Biodata General 1Adult
Weight (8 - 10 weeks old) Male Sprague Dawley Female Sprague Dawley 1Life Span 1Body Surface Area 1Chromosome Number (Diploid) 1Water Consumption 1Food Consumption 1Body Temperature Floor Area (Sapanski, 1984)
275 g 225 g 2 – 5 years 0.03 – 0.06 cm2 42 80 – 110 ml/kg/day 100 g/kg/day 37.5ºC (99.5ºF) 29 – 40 in2
9Anatomy:
Harderian gland secretes red pigmented tears, color-blind, lacking some water taste receptors, no tonsils/ gall bladder/ sweat glands, thermoregulates via tail 9Behavior:
Nocturnal, passive, curious, intelligent, practice coprophagy (recycle feces), light and noise sensitive, group or singly housed 7Organ
Weights Adrenals Brain Heart Intestine
76
0.05 g 1.8 g 1.0 g 11.25 g
2.0 g 10.0 g 1.5 g 0.75 g 167 ml* 92.8 ml* 74.2 ml* 25 g/week *250 g rat
Reproductive 1Breeding
Age Season Breeding Life (Sapanski, 1984) 1Gestation 10Pseudopregnacy Length 10Duration of Single Cycle 1Breeding
50 – 60 days none 1.5 years 21 – 23 days 12 days 4 - 5 days
10Stages
of Sex Cycle Polyestrous Female Stage 1 dioestrous Stage 2 pro-estrous (early) Stage 3 pro-estrous (late) Stage 4 oestrous Stage 5 metoestrous
5Time
of Ovulation
5Type
of Ovulation
6 hours 60 hours 12 hours 10 -20 hours 8 hours 8 – 11 hours after estrous spontaneous
5Mating
Methods
5Fertilization 5Number
of Eggs Shed of Eggs 5Litter Frequency 9Mammary Glands 9Litter Number 9Birth Weight 9Eyes Open 9Weaning Age 5Viability
Monogamous Or trios 7 – 10 hours after ovulation 10 + 10 -12 hours 7 – 9 /year 6 pairs 8 – 14 pups 5–6g 10 – 12 days 21 days
Cardiovascular 7Blood
Volume
7Hematocrit 7Blood
pH Volume 7Plasma Albumin 7Plasma -1-ACG 7Plasma
58 ml/kg 46% 7.38 31.3 ml/kg 31.6 mg/ml 18.1 mg/ml
Muscle Portal Vein Skin Spleen 1Heart
rate Pressure – systolic 1Blood Pressure – diastolic 1Cardiac Output 1Minute Volume 1Stroke Volume 1Plasma pH 1Plasma CO2 1Plasma CO2 Pressure 1Blood
7.5 9.8 5.8 0.63 330 - 480 beats/min 88 – 184 mmHg 54 – 145 mmHg 10 – 80 ml/min 0.05 – 0.101 ml 1.3 – 2.0 ml/beat 7.4 22.5 mM/l 40 mmHg
1Leukocyte
Counts Total Neutrophils Lymphocytes Monocytes Eosinophils Basophils
14 x 103/ml 22% 73% 2.3% 2.2% 0.5%
1Platelets 7Blood
Flow Adipose Brain Heart Hepatic Artery Intestine Kidneys Liver
(ml/min) 0.4 1.3 3.9 2.0 7.5 9.2 13.8
1240 x 103/ml Cell Volume (PCV) 46% 1Red Blood Cells 7.2 – 9.6 x 106/min3 1Hemoglobin 15.6 g/dl 6Clotting Time 20 seconds 10Osmolality 321 mmol/kg 10Whole Blood Specific Gravity 1.05 9Mean Corpuscular Volume (MCV) 46 – 65 fl 1Packed
77
9Mean
Corpuscular Hb Concentration (MCHC) 31 – 40 g/dl 9Mean Corpuscular Hb (MCH) 18 – 23 pg 9Reticulocytes 0 – 25%
Urine 1pH
7.3 – 8.5 Gravity 1.04 – 1.07 3Urine Flow 50 ml/day 2Osmolality 2442 mOsm/kg 2Protein <30 mg/dl 2Creatinine 5.5 mg/100g/day 2Potassium 2.2 mEq/100g/day 217-ketosteroid 16.4 μg/100g/day 10Urea 442.5 mmol/l 10Ureate 1.7 mmol/l 10Na+ 229 mmol/l 10K+ 149.5 mmol/l 10Ca2+ 0.7 mmol/l 7Number of Glomeruli 2.9 x 105/kg 9L-amino acid oxidase in kidneys is significant only in rats 1Specific
Metabolism 5Basal
Metabolic Rate of 300g rat (surface area of 0.04m2 and 3,357,813 joules/m2/day = 802 kcal/m2/day) 3
-Glucuronidase Activity Proximal Small Intestine = 304 nmol substrate/hr/g Distal Small Intestine = 1341 nmol substrate/hr/g
7Liver
Cytochrome P450 = 0.98 nmol/mg protein
Respiratory 9Respiratory
Rate Consumption 5Ventilation Rate 5Tidal Volume 9Trachea diameter 9Total lung capacity 3Oxygen
78
70 – 115 breaths/ min 0.84 ml/hr/g 66 – 210 breath/min 0.60 – 1.25 cm3/g/hr 1.6 – 7.7 mm 9.9 – 12.7 ml
Gastrointestinal 7Small
Intestine Transit Time 7Small Intestine Length 7Large Intestine Length 7Whole Intestine Volume 7Gut Lumen Volume 7Fasted Stomach pH 7Postprandial Stomach pH
88 min 0.1 – 0.15 m 0.02 – 0.03 m 11.25 ml 8.8 ml 3.0 – 3.8 2.3 – 4.5
7Fasted
Intestine pH pH 9Duodenum length 9Jejunum length 9Ileum length 7Feces
6.9 – 7.8 6.9 10 cm 100 cm 3 cm
Clinical Chemistry Values 10Total
proteins
63 g/l 28 g/l 10 -1 Globulins 4.6 g/l 10 -2 Globulins 3.5 g/l 10 -Globulins 5 g/l 10Gamma Globulins 4.4 g/l 10Urea 6.9 mmol/l 10Ureate 0.6 mmol/l 10Glucose 10.1 mmol/l 10Creatinine 42.5 μmol/l 10Creatine Clearance 1.2 ml/min 10Total Lipids 2.3 g/l 10Phospholipid 0.05 g/l 10Cholesterol 1.9 mmol/l 10Neutral Fat 0.8 g/l 10Bilirubin 2 μmol/l 10Aspartate aminotransferase 82 i.u./l 10Creatinine kinase 368 i.u./l 10Gamma-glutamyl transpeptidase 10 i.u./l 10 -hydroxybutyrate dehydrogenase 71 i.u./l 10Iron Binding Capacity 101 μmol/l 10Specific Gravity (cm water) 1.21 10Albumin
Bile 7Bile
Flow
90 ml/kg/day
Brain 7Blood
Volume in Brain 7CSF Flow 9CSF Volume 4Choroid Plexus Blood Volume
11 μl/g tissue 2.2 μl/min 234 - 266 μl 13.1 μl/g tissue
8Solute
mEq/Kg H2O 152 3.36 2.22 1.77 5.38 0.184 2.08 34 – 42 mmHg
Concentrations in CSF Na K Ca Mg Glucose Pyruvate Lactate 9CSF pressure
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10Fe3+ 10Na+ 10K+ 10Ca2+ 10Cu+ 10Mg2+ 10Cl-
28 μmol/l 135 mmol/l 4.9 mmol/l 2.6 mmol/l 17.8 μmol/l 1.3 mmol/l 100 mmol/l
_______________________________________________________ 1Cassella
J. et al., The Rat Nervous System, John Wiley and Sons, New York, 1997. H. et al. (eds.), The Laboratory Rat, Volume 1: Biology and Diseases, Academic Press, New York, 1979. 3Davies B. and Morris T., Physiological parameters in laboratory animals and humans, Pharmaceutical Research, 10(7): 1093 – 1095, 1993. 4Davson H. and Segal M. (eds.), Physiology of the CSF and Blood-brain Barriers, CRC Press, New York, 1996. 5Inglis J., Introduction to Laboratory Animal Science and Technology, Pergamon Press, New York, 1980. 6Joint Working Group on Refinement, Removal of blood from laboratory mammals and birds, Laboratory Animal, 27: 1 – 22, 1993. 7Kwon Y., Handbook of Essential Pharmacokinetics, Pharmacodynamics, and Drug Metabolism for Industrial Scientists, Kluwer Academic Press, New York, 2001. 8Ohno K. et al., Lower limits of cerebrovascular permeability to nonelectrolytes in the conscious rat, American Journal of Physiology, 235(3): H299 – H307, 1978. 9Sharp P. and LaRegina M., The Laboratory Rat, CRC Press, New York, 1998. 10Waynforth H. and Flecknell P, Experimental and Surgical Technique in the Rat, Academic Press, New York, 1992. 2Baker
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Spatial Definitions The author has attempted to relate the step-bystep procedure in a clear, universally understood language. However, in the world of surgery and medicine, the terminology used is a language of its own. This reference section should give the reader a brief idea of the most common terms; their definition and usage.
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Sagittal plane: longitudinal cross-section from cranial to caudal Coronal plane: longitudinal cross-section from dorsal to ventral Transverse plane: lateral cross-section at midline Median plane: longitudinal cross-section at the midline
An example of correct usage is as follows: “…an incision was made in the ventrolateral aspect of the neck. The right external jugular vein was dissected free of surrounding fascia and stabilized with two loops of 4-0 silk suture. The distal loop was tied to ligate the vein on the cranial aspect. Venotomy was made approximately five millimeters cranial to the site of crossover by the pectoralis major muscle… A subcutaneous tunnel was created from the neck area to the dorsum, and the catheter was pulled through to exit through an incision in the interscapular area. A subcutaneous pocket in the interscapular region was created by blunt dissection.” ~ Foley, 2002.
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Latin Terms Abbreviation
Expanded form
Definition
ad lib. A.M. b. b.i.d. bol. brevis cap. caps. i.c. lb. m. m. dict. m.t.d. n. nebul. n. et m. noct. o.d. omn. Hor.
ad libitum ante meridian bis bis in die bolus brevis capiat capsula inter cibos libra mane more dicto mitte tales doses naris nebula nocte maneque nocte octus dexter omni hora
at pleasure before noon twice twice a day a large pill short let the patient take a capsule between meals pound in the morning as directed send such doses nostril a spray night and morning at night right eye at every hour
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Abbreviation
Expanded form
Definition
o.s. p.c. P.M. p.o. ppt. pro rect. q., qq. q.i.d. qq. hor q.s. quot. Op. sit sol. s.o.s. ss. stat. syr. tab. t.i.d. ung., ungt. vesp.
oculus sinister post cibos post meridiem per os praecipitus pro recto quodque,quaeque quarter in die quaque hora quantum sufficiat quoties opus sit solubilis si opus sit semis statim syrupus tabella ter in die unguentum vesper
left eye after meals after noon by mouth precipitated rectal each, every four times a day every hour a sufficient quantity as often as necessary soluble if there is need one half immediately syrup tablet three times a day ointment evening
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Resources Vendors Braintree Scientific P.O. Box 850929 Braintree, Massachusetts 02185 www.braintreesci.com 781-843-2202 Decapicones, gas chamber, tubing, tethers, suture, sterilizer, balance, wound clip system, warming pad, heat lamp, restrainer, microscope, PVC Rat, ThermoCare ICU Ancare P.O. Box 814 Bellmore, New York 11710 www.ancare.com 919-620-7504 Nestlets, caging Henry Schein 135 Duryea Road Melville, New York 11747 www.henryschein.com
800-V-SCHEIN Sterilizer bags, needles, heparin,vetbond,atropine sulphate, IV saline bags, paralube, sterile saline, buprenorphine, ketamine, acepromazine, xylazine, gauze, betadine wipes, alcohol wipes, antibiotic Samuel Perkins Co., Inc. 497 Beale Street Quincy, Massachusetts 02169 617-773-3600 Heating pad, bone wax George Tiemann 25 Plant Avenue Hauppauge, New York 11788 www.georgetiemann.com 800-843-6266 3-0 silk suture (100 yards)
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Harvard Apparatus 22 Pleasant Street South Natick, Massachusetts 01760 800-272-2775 Glass bead sterilizer, spear-shaped sponges, ThermoCare ICU Roboz PO Box 10710 Gaithersburg, Maryland 20898 www.roboz.com 301-590-0055 Surgical instruments, wound clips and applier, wound clip remover Leica 90 Boroline Road Allendale, NJ 07401 www.leica-microsystems.com 800 526 0355 MZ6 dissecting scope Baxter Scientific One Baxter Parkway Deerfield, IL 60025
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www.baxter.com 800-422-9837 Surgical board J.A. Webster 86 Leominster Road Sterling, Massachusetts 01564 800-225-7911 A5 clippers, 40mm clipper blade, fenestrated towels, 5% dextrose VWR 1310 Goshen Parkway West Chester, PA 19380 www.vwr.com 800-932-5000 Small and large underpads, Sartorius animal weighing scale and printer, gavage needles, broome restrainers, PE50 tubing, syringes Fisher Scientific 2000 Park Lane Drive Pittsburgh, PA 15275 www.fisherscientific.com 800-766-7000 Cotton applicators, insulin syringes
Hazard Technologies 406 Headquarters Drive #5 Millersville, Maryland 21108 410-987-7833 Vacuum/clipper system Lab Products 742 Sussex Avenue Seaford, Delaware 19973 800-526-0469 Caging equipment Bio-Serv One 8th Street, Suite 1 Frenchtown, NJ 08825 908-996-2155 www.bio-serv.com Nutra-Gel, enrichment
Surgical Specialties 10 Dennis Drive Reading, Pennsylvania 19606 www.sharpoint.com 800-523-3332 Sharpoint PracticePak Charles River Labs 251 Ballardvale Street Wilmington, Massachusetts 01887 800-LAB-RATS www.criver.com Rats, Transgel® Harlan P.O. Box 29176 Indianapolis, Indiana 46229 317-894-7521 Rats
Boston Tec 2700 James Savage Road Midland, MI 48642 989-496-9510 www.bostontec.com Hydraulic tables
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Clear H2O 117 Preble Street Portland,ME 04101 888-493-7645 www.clearh2o.com HydroGel™ Taconic 273 Hover Avenue Germantown, New York 12526 www.taconic.com 518-537-5200 Rats
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Websites Animal Science Associations American Association for Accreditation of Laboratory Animal Science (AALAC) www.aaalac.org American Association for Laboratory Animal Science (AALAS) www.aalas.org American Committee on Laboratory Animal Diseases (ACLAD) www4.ncsu.edu/unity/users/b/bweigler/Web/ACLAD/Index.html Institute of Laboratory Animal Resources (ILAR) www2.nas.edu/ilarhome Lab Animal Magazine www.labanimals.com USDA Animal and Plant Health Inspection Service www.aphis.usda.gov/vs/vshome.html Food and Drug Administration (FDA) www.fda.gov/fdahomepage.html
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Laboratory Animal Science Association (LASA) www.mandm.ncl.ac.uk/lasa.html Laboratory Animal Welfare Training Exchange (LAWTE) netvet.wustl.edu/org/lawte/homepg.htm Wound closure http://ethicon.com/page/pdf/WoundClosureManual101702.pdf Suture Tying www.jnjgateway.com/public/USENG/5256ETHICON_Encyclopedia_of_Knots.pdf Disinfectants www.fda.gov/cdrh/ode/germlab.html Principles of Surgery http://cal.vet.upenn.edu/surgery/index.htm Surgical Equipment and products www.MyNeurolab.com Fluid Administration Alza Scientific Products www.alza.com
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Glossary Acclimate – to become familiar with new surroundings Amnesia – loss of memory Anaerobic glycolysis – breakdown of sugar in absence of oxygen Analgesia – agent which blocks the perception of pain without loss of consciousness Anemia – condition caused by low red blood cell count Anesthetic – agent which reduces or eliminates sensory and motor responses accompanied by loss of consciousness Anterior – situated toward the front or head
Anti-emetic – agent which suppresses nausea; useful for motion sickness Asepsis – a state of sanitation in which microorganisms are greatly reduced Autoclave – machine that sterilizes by high temperature and high pressure Barbiturates – group of sedative drugs derived from barbituric acid Baroreceptor – receptor that senses or controls pressure changes Biocompatible – mixture of two substances resulting in no adverse reaction Bronchodilation – opening of bronchi; two tubes at the lower end of the trachea Cadaver – a dead body
Antibiotic – agent that kills bacteria
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Catheter – tubing through which blood or other fluids can flow
Connective tissue – tissue which connects or supports other cells or tissues
Cardiac output – the rate at which blood is pumped out of the ventricles of the heart
Coprophagy – a nutritive practice by rodents and rabbits of recycling feces
Catalepsy – sustained immobility
Cornea – a convex membrane covering the iris of the eye
Caudal – situated towards the tail Cranial – situated towards the head Cautery – device used to apply direct heat for the purpose of coagulating blood
Cryosurgery – surgery using freezing probe in place of scalpel knife
Cerebral – pertaining to the two cerebrum halves of the brain, which control motor and sensory function
Cumulative dosing – additive effect of multiple dosing
Cholinergic – refers to parasympathetic nerves which release acetylcholine
Decapicone – plastic cone-shaped bag used as a restraint for rodents
Collateral – secondary
Diarrhea – loose stool
Concentric – having a common middle
Dilate – to widen or enlarge
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Dissociative anesthetic – an anesthetic agent which disconnects motor and sensory responses
Distal – situated away from a specified point Diuresis – increased urine output
Extravasation – fluid escaping outside of vessel First pass metabolism – refers to process following oral administration whereby first pass through GI and liver results in breakdown or extraction of substance and less compound reaches circulation
Dorsal recumbency – lying on the back Dyspnea – labored breathing Edema – an abnormal swelling due to accumulation of interstitial fluid Embolism/emboli – blockage by solid particle, clot, or air bubble in circulation
Gavage – a method of oral administration directly to the stomach Gross – visible by eye only Hematocrit – percent of packed cell volume (PCV); volume of red blood cells
Endothelium – membranous lining
Hematoma – abnormal accumulation of blood
Enzootic – a type of disease which occurs in one or more classifications of a population e.g. newborns
Hemorrhagic shock – a circulatory imbalance due to extreme loss of blood volume Hepatic – pertaining to the liver
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Homeostasis – internal equilibrium maintained by adjusting physiological processes
Hypoxia – a condition characterized by a decrease of oxygen in the tissues Interstitial fluid – fluid between cells
Hybrid – mixture of characteristics from two or more sources Hypercapnia – excessive CO2 in blood Hyperglycemia – a condition characterized by excessive sugar in the bloodstream Hyperoxic ventilation – respiration resulting in increased oxygen Hyperventilation – an increase in respiratory rate, depth, and duration Hypothermia – below normal body temperature
Intramuscular – within a muscle Intraperitoneal – within the abdominal cavity but not inside the abdominal organs Intrathecal – within the subarachnoid spaces that contain cerebrospinal fluid Intravascular – within the blood vessel Intravenous – within the vein Isothermic – temperature that is maintained at a constant setting Laryngeal – of the larynx; the voice organ
Hypovolemic shock – a condition characterized by a severe decrease in circulating blood volume
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Latent – dormant or inactive state
Lateral – situated away from the middle of the body
Obturator – a device that causes a stoppage
Limbic – periphery or edge of main structure
Occlude – to cause a closure
Lipid soluble – ability to dissolve in fatty acid
Palpate – manual examination
Medial – situated towards the middle of the body
Palpebral – pertaining to the eyelid
Medulla – upper portion of spinal cord Metabolic – intracellular process that breaks down compounds
Parasympatholytic – that which neutralizes effect of parasympathetic stimulation Patent – open and clear Pedal – pertaining to the foot
Metabolic acidosis – depletion of alkali reserves Mortality – rate of death Mucous membrane – glands which secrete mucus
Perioperative – surrounding the operation Pharmacokinetics – the study of the way molecules behave in the body Pharyngeal – pertaining to the pharynx; a cavity at the back of the mouth
Nocturnal – exhibits most active behavior at night
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Porphyrin – red pigment secreted by the harderian gland behind the eye that may protect from light
Splenocyte – cells found in the spleen
Posterior – situated toward the back
Sternal recumbency – lying on front or sternum
Sterile – free from microorganisms
Quarantine – period of isolation from established population
Subcutaneous – underneath the skin
Renin-angiotensin system – kidney enzymesubstrate action that affects blood pressure
Subcuticular suture – sutured beneath the cuticle of the skin
Rostral – situated towards the nose
Sympathetic – pertaining to autonomic nervous system; nerves which extend to all muscles
Secretion – fluid passed from gland to GI, blood, or exterior Sedative – an agent that calms and lessens functional ability
T cell – a type of immune cell called a lymphocyte Tachycardia – rapid beating of heart
Self-mutilation – A behavior or disease in which rats bite and scratch themselves Sensory cortex – area of the brain pertaining to sensation
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Tachypnea – abnormal respiration Tissue anoxia – lack of oxygen in tissues
Thermoregulation – self-regulation of body heat
Ventral – situated towards the front of a rat Venotomy – an incision performed on a vein
Transducer – device which transfers power between systems for the purpose of measuring pressure, temperature, speed, etc.
Zoonotic – a type of disease which is transmitted between animals and humans
Unilateral – pertaining to one side Vagal tone – refers to regulation of heart rate by manipulations to the vagus nerve Vasoconstriction – the narrowing of a vessel wall lumen Vasodilation – the widening of a vessel Vasospasm – vessel wall constrictions Vasovagal – pertaining to reflex action between vagus nerve and circulation causing heart to slow down; blood pressure and oxygen decrease result in patient fainting
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Biography With a degree in Veterinary Science from the University of Massachusetts at Amherst, Ms. Heiser has spent over 20 years perfecting these surgical techniques in various academic and industrial settings. Her experience covers many disciplines including toxicology, neuro- & ocular pharmacology, cell biology, and pharmacokinetics. She has authored & co-authored over 15 scientific publications. In addition, she has served over a decade as a member and cochair of IACUCs. She was appointed and serves as a board member of the New England Branch of AALAS. She is employed as a Lab Animal Resources manager at a major pharmaceutical company and lives in Massachusetts with her husband, two children, dog, rabbit, & bearded-dragon.
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Index A Acclimate, 3, 68, 91 Acepromazine, 7, 9, 38, 85 Allergens, 19 Alpha2-antagonist, 11 Amnesia, 10, 91 Analgesia, pre-operative, 9, 91 Anatomy, 29, 31, 32, 34, 76 Anemia, 67, 91 Anesthesia, 3, 5, 6, 7, 9, 10, 11, 13, 14, 24, 35, 91 acepromazine, 7, 9, 38, 85 alpha2-antagonists, 11 atipamazole, 11 dissociative, 10 hepatic clearance, 10, 77, 93 injectables, 3, 6, 10 ketamine, 7–11, 35, 38, 85 mode of action, 10 recovery, 3–6, 9, 10, 12, 14, 15, 16, 26, 35, 65 stages of, 9, 14 tolazoline, 11 xylazine, 7, 9, 11, 38, 85 yohimbine, 11, 90 Animal welfare, 90 Act, 15
Anterior, 32, 39, 41, 52, 53, 91 Anti-emetic, 9, 91 Antibiotic, 3, 16, 85, 91 Arterial blood collection, 1 catheterization, 73 pressure, 66 Aseptic, technique, 15, 19 Atipamazole, 11 Atropine, 5, 65, 85 Autoclave, 17, 91 B Banamine, 4 Barbiturate, 9, 91 Behavior, 3, 95, 96 Betadine, 16, 18, 40, 85 Blood clots, 26 flow, 23, 31, 32, 45, 56, 63, 69 gases, 74 loss, 24, 28, 66, 67 Blood pressure, 24, 27, 34, 66, 69, 74, 96, 97 Blood sampling, 27, 59, 66, 67, 68, 73
automatic blood sampler, 27, 73 intra-arterial, 73 troubleshooting, 68, 69 volumes, 25, 66, 67, 93, 94 Body temperature, 4, 24, 38, 67, 68, 94, 97 Body weight, 3, 8, 31 gain, 6 loss, 6 obesity, 11, 12 Bolus, 71, 83 Bone wax, 26, 48, 59, 68, 69, 85 Buprenorphine, 4 C Cadaver, 34, 91 Cardiac, 4, 9, 10, 14 abnormalities, 33 distress, 14 monitoring, 73, 74 output, 10, 66, 92 Carotid artery, 4, 28, 29, 31, 32, 33, 35, 49–66, 68, 73 Catheter, 1, 5, 23, 26, 48, 50, 56, 57, 59, 60–62, 64, 66, 68, 69, 72, 92 chewing, 65 111
flush, 17, 28, 48, 59,68, 69 heparin-coated, 26 hybrid, 27 insertion, 31, 34, 46, 47, 56, 61, 63, 64, 71, 73 leakage, 11 location, 31 perflourocarbon, 28 polyethylene, 26 polyvinyl, 28 pre-constructed, 28 preparation, 17, 28 silicon (silastic®), 27 Tygon®, 28 Caudal, 82, 92 CBV, 66, 94 Cerebral blood flow, 10 Cholinergic, 66, 92 Cidex, 17 Circle of Willis, 32 Clidox, 17 Clots, 26, 27, 48, 68, 69, 93 CNS, 9, 14, 65, 73 Contamination, 15, 26 Continuous infusion, 27, 70–72 Cornea, 92 corneal injury, 18 protection, 18 reflex, 13 112
Corticosterones, 1 Cranial, 82, 92 Cryosurgery, 24, 92 CYP inhibition, 11 D Decapicone, 38, 85, 92 Diarrhea, 3, 92 Dilate, 92 Discharge, 3 Disinfectant, 15, 16, 17, 19, 90 cidex, 17 clidox, 17 novalsan, 17 sonacide, 17 sporocidin, 17 Dissection, 82 scope, 20, 21, 86 Distal, 31, 78, 82, 93 Diuresis, 9, 93 Dorsal, 82 recumbency, 39, 93 Dose, 70, 83 analgesia, 9 anesthetic, 3, 7, 9, 10, 11 atropine, 5 cumulative, 92 gavage, 70
Drapes, 16, 17, 18, 37, 40 Dyspnea, 93 E Ear pinna reflex, 13 Edema, 5, 6, 93 Embolism, 71, 93 Enzootic disease, 3, 93 Euthanasia, 16 Extravasation, 27, 93 F Fasting, 4 Fat, 10, 11, 12, 41, 79 Fill solution, 26, 72 heparinized glucose, 26 heparinized PVPD, 26 heparinized saline, 26, 46, 48, 56 Fluid volume, 24, 25, 66 Flunixamine, 4 Flunixin, 4 Fur matting, 3 G Gavage, 70, 86, 93 H Hair removal, 18, 39 Heart rate, 5, 9, 10, 14, 66, 74
Heating pad, 4, 5, 26, 38, 65, 69, 85 Hemolysis, 71 Hemostasis, 4, 24 Heparin, 26, 46, 48, 57, 59, 68, 69, 85 Hormonal, 3, 66 Housing, 3, 5, 6 group, 6, 76 homecage, 3 individual, 5, 6, 65, 69, 76 Humane animal use, 1, 67 Hydraulic table, 20, 87 Hydrogel™, 5, 88 Hyperglycemia, 9, 94 Hyperventilation, 21, 67, 94 Hypothermia, 9, 24, 94 I Incision, 15, 18, 24, 37, 40, 49, 60, 82, 97 preparation, 18 Indwelling catheters, 1 Injection, 14, 68 bolus, 71, 83 continuous infusion, 71 intramuscular, 38, 70, 94 intraperitoneal, 65, 70, 94 intravenous, 70, 71, 94
multiple, 11, 92 oral, 93 slow push, 71 subcutaneous, 70, 96 volume, 7, 70, 71 Instruments, 15, 17, 19, 36, 39, 86 Intravenous, delivery, 70, 71 J Jugular vein, 1, 28, 29, 30, 31, 40, 41, 42, 49, 50, 62, 82 K Ketamine, 7, 8, 9, 10, 11, 35, 38, 85 L Latent disease, 3, 94 M Metabolic, 3, 66, 78, 95 Motor function, 6, 91, 92, 93 N National Institutes of Health (NIH), 15 Needle gauge, 11, 38, 46, 48, 56, 59, 68, 71, 85, 86 NIH, 15 Novalsan, 17 Nutra-Gel, 5, 87
O Observation, 3, 4, 5, 6, 41, 45, 46 Obturator, 26, 68, 69, 95 Occlusion, 32, 68, 95 Ophthalmic ointment, 16, 18 Oral administration, 70, 86, 93 Oral gavage, 70, 86, 93 Orbital sinus, 1 Overdose, 11, 12, 14 P Pain, 3, 6, 9, 15, 20, 65, 91 Palpebral reflex, 13, 95 Parasympatholytic, 5, 92, 95 Patency, 2, 26, 27, 69, 95 Pedal withdrawal reflex, 13, 95 Perflourocarbon, 28 Perioperative care, 3, 95 intra-operative, 3, 4 post-operative, 3, 5, 65 pre-operative, 3 Pharmacokinetics, 65, 67, 95 Phthalates, 27 Physical exam, 3, 6, 9 Platelets, 1, 24, 77 Posterior, 32, 43, 45, 52, 55, 56, 57, 58, 62, 96 113
Posture animal, 4 surgeon, 18, 20 PracticePak, 22, 34, 87 Pre-analgesic, 3 Q Quarantine, 3, 96 R RBC, 25, 31, 77, 91, 93 Recovery, 3, 4, 5, 6, 9, 10, 12, 14, 15, 16, 26, 35, 65 acute, 5 long term, 6 Red blood cells, 25, 31, 77, 91, 93 Reflexes, 9, 10, 13, 14, 39, 66, 67, 97 corneal, 13 ear pinna, 13 palpebral, 13 pedal, 13 tail pinch, 13 toe pinch, 13 Respiration, 4, 6, 9, 14, 51, 67, 78, 94, 96 S Salivation, 5, 10, 50 Sanitization, 15, 91 114
Sedative, 9, 91, 96 Self-mutilation, 5, 6, 96 Silastic®, 27 Silicon, 17, 27 Skin, 3, 4, 13, 34, 40, 41, 44, 60, 61, 62, 63, 66, 77, 96 microbes, 26 preparation, 18 Sonacide, 17 Splenocyte, 12, 96 Sporocidin, 17 Sprague Dawley female, 7, 8, 11, 76 male, 7, 8, 11, 76 Sterilization, 7, 15, 18, 85, 96 autoclave, 17, 91 gas, 17 glass bead, 16, 17 Stopper, 26 Stress, 1, 3, 6, 35, 68, 73 Surgical plane, 9, 11, 13, 14 Sympathetic nerve, 52, 66, 92, 95, 96 T Tachycardia, 66, 96 Tail pinch reflex, 13 vein, 1
T-cell, 12 Toe pinch reflex, 13 Tolazoline, 11 Transgel®, 5, 65, 87 Tubing, 48, 85, 92 polyethylene, 27, 86 silicon, 17 V Vagus nerve, 33, 52, 54, 56, 65, 66 vagal tone, 5, 97 Variability, 15, 31 Vaso-constriction, 31, 35, 66, 68, 97 Vein pressure, 28 venotomy, 45, 47 Vertebral, arteries, 32 Vessel, 31, 94 vaso-constriction, 31, 35, 66, 68, 97 vasodilation, 97 vasospasm, 97 W Wound closure, 5, 90 knot tying, 22, 23 subcuticular, 5, 96
suture, 5, 6, 15, 17, 33, 34, 39, 42, 44, 45, 47, 53, 54, 55, 56, 57, 58, 85, 90, 96 wound clips, 5, 12, 39, 61, 62, 63, 64, 85, 86 X Xylazine, 7, 9, 11, 38, 85 Y Yohimbine, 11 Z Zoonotic, 97
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